CN117460877A - Perforating gun with timing self-sealing threads - Google Patents

Abstract

A perforating gun system, including: a first perforating gun having a housing, the first perforating gun housing having a first end, a second end with a first alignment mechanism and a second end with the alignment mechanism a first set of aligned cuts; a second perforating gun having a housing having a first end and a second set of cuts, the first end having a second perforating gun with a second set of cutouts; The first alignment mechanism at both ends is connected to a second alignment mechanism, and the second set of cutouts is aligned with the second alignment mechanism. Wherein, the connection between the first perforating gun and the second perforating gun aligns the first set of incisions with the second set of incisions.

Description

Perforating gun with timing self-sealing threads

Cross Reference to Related Applications

The present application claims priority from U.S. provisional patent application 63/197,257 filed on day 4 of 6 of 2021.

Background

Typically, when a subterranean well for producing fluids, minerals or gases from a subterranean reservoir is completed, several types of tubulars are placed downhole as part of the drilling, exploration and completion process. These tubulars may include casing, tubing, piping, liners, and devices that are conveyed downhole through various types of tubulars. Each well is unique and thus a combination of different tubulars can be lowered into the well for a variety of purposes.

Subsurface or subsurface wells pass through one or more formations. The formation is a rock or body of formation that contains one or more components. The formation is considered a continuum. Hydrocarbon deposits may be present in the formation. Typically, a wellbore is drilled from a surface location into the target formation. Completion equipment will be placed in place, including casing, tubing, and other desired downhole equipment. Perforating casing and formation with perforating guns is a well known in the art for accessing hydrocarbon deposits in the formation from a wellbore.

Perforating a formation using shaped charges is a well known method of completing an oil well. Shaped charges are a term of art for devices that, when detonated, produce focused output, high energy output, and/or high velocity jets. This is achieved to some extent by the geometry of the explosive and the adjacent liner. Generally, shaped charges comprise a metal housing containing a concave explosive material therein, the metal housing having a thin metal liner on its inner surface. Many materials are used for bushings; some of the more common metals include brass, copper, tungsten, and lead. When the explosive is detonated, the liner metal is compressed into a superheated ultra-high pressure jet that can penetrate the metal, concrete and rock. Perforating charges are typically used in groups. These perforating charge packs are typically held together in an assembly known as a perforating gun. Perforating guns come in many types, such as bar guns, cartridge-type perforating guns, port plug guns, and disposable hollow carrier guns.

The perforating charges are typically detonated by detonating cords near a detonating hole in the top of each charge housing. Typically, the detonating cord terminates near the end of the perforating gun. In this arrangement, an initiator located at one end of the gun may detonate all of the perforating charges in the gun and continue ballistic transfer to the opposite end of the gun. In this way, multiple perforating guns may be connected end to end, with one initiator firing all of the perforating guns.

The detonating cord is typically detonated by an initiator triggered by the firing head. The firing head may be driven in a variety of ways including, but not limited to, electronically, hydraulically, and mechanically.

Disposable hollow carrier perforating guns are typically made from standard sized steel tubing with internally threaded ends having internal/female threads at each end. A pin end adapter or fitting having male/external threads is threaded through one or both ends of the gun. These fittings may connect the perforating gun together, connect the perforating gun to other tools (such as setting tools and collar positioners), and connect the firing head to the perforating gun. The joints are typically equipped with electronic, mechanical, or ballistic components for activating or controlling the perforating gun and other components.

Perforating guns typically have a cylindrical gun body and a charge tube, or loading tube, that contains the perforating charge. The gun body is typically constructed of metal and is cylindrical. The charge tube may be formed as a tube, a strip or a chain. The charge tube will contain a cutout called a charge hole to accommodate the shaped charge.

Disclosure of Invention

Exemplary embodiments may include a perforating gun system. The perforating gun system includes a first perforating gun having a housing and a second perforating gun having a housing. The housing of the first perforating gun has a first end, a second end with a first alignment mechanism, and a first set of cuts aligned with the alignment mechanism. The housing of the second perforating gun has a first end with a second alignment mechanism coupled to a first alignment mechanism of the second end of the first perforating gun and a second set of cuts aligned with the second alignment mechanism. Wherein the first perforating gun is connected with the second perforating gun so that the first set of cuts are aligned with the second set of cuts.

Variations of the exemplary embodiment may include the first alignment mechanism being a timed external thread. The second alignment mechanism may be a timed external thread. The perforating gun system may have at least one o-ring seal between the second end of the first perforating gun and the first end of the second perforating gun. The perforating gun system may have a positive stop at the full junction between the second end of the first perforating gun and the first end of the second perforating gun. The positive stop may be a ramp that prevents rotation beyond a predetermined point of thread engagement. The limit stop may be a 45 degree incline. The timed external thread and the timed internal thread may be self-sealing. The perforating gun system may include a positive stop at a full junction between the second end of the first perforating gun and the first end of the second perforating gun. The positive stop may be a ramp that prevents rotation beyond a predetermined point of thread engagement. The limit stop may be a 45 degree incline.

Exemplary embodiments may include a perforating gun system. The perforating gun system includes a first perforating gun having a housing and a second perforating gun having a housing. The housing of the first perforating gun has a first end, a second end with a timed external thread, and a first set of cuts aligned with the timed external thread. The housing of the second perforating gun has a first end with a timed internal thread for connection to the second end of the first perforating gun by a timed thread and a second set of cuts aligned with the timed internal thread. Wherein the timed external thread fully engages the timed internal thread to align the first set of cuts with the second set of cuts.

Variations of the perforating gun system may include at least one o-ring seal between the second end of the first perforating gun and the first end of the second perforating gun. The perforating gun system may include a positive stop at a full junction between the second end of the first perforating gun and the first end of the second perforating gun. The positive stop may be a ramp that prevents rotation beyond a predetermined point of thread engagement. The limit stop may be a 45 degree incline. The timed external thread and the timed internal thread may be self-sealing.

Exemplary embodiments may include a method for assembling a perforating gun string (a perforating gun string). The method comprises the following steps: screwing the first timing thread of the first perforating gun into the second timing thread of the second perforating gun; aligning a first set of cuts on the first perforating gun with a second set of cuts on the second perforating gun; the first timing thread of the first perforating gun is fully engaged with the second timing thread of the second perforating gun. Wherein full engagement of the first perforating gun with the second perforating gun aligns the first set of cuts with the second set of cuts.

Variations of the exemplary embodiment may include: the positive stop is engaged when the first timing thread of the first perforating gun is engaged with the second timing thread of the second perforating gun. The method may include fully engaging the first perforating gun with the second perforating gun such that a pressure seal is provided between an interior of the perforating gun string and an exterior of the perforating gun string.

Drawings

For a thorough understanding of the exemplary embodiments, reference is made to the following detailed description of the preferred embodiments, taken in conjunction with the accompanying drawings, in the several figures of which reference numerals identify the same or similar elements. In short:

FIG. 1 is a side view of a perforating gun having self-sealing tapered threads.

FIG. 2 is a partially transparent view of a perforating gun having self-sealing tapered threads.

FIG. 3 is a cross-sectional view of two perforating guns interconnected with timed self-sealing tapered threads.

Fig. 4 is a cross-sectional view of a perforating gun having self-sealing tapered threads.

FIG. 5 is a cross-sectional view of the connection between two interconnected perforating guns having self-sealing tapered threads.

FIG. 6 is a perspective view of two perforating guns interconnected with timed self-sealing tapered threads.

FIG. 7 is a perspective view of the connection between two interconnected perforating guns having timed self-sealing tapered threads.

FIG. 8 is a partial cross-sectional view of the connection between two interconnected perforating guns having timed self-sealing tapered threads.

Detailed Description

In the following description, certain terminology is used for the sake of brevity, clarity, and example. This is not meant to be limiting, and these terms are used for descriptive purposes only and are intended to be broadly construed. The various apparatus, systems, and method steps described herein may be used alone or in combination with other apparatus, systems, and method steps. It is contemplated that various equivalents, alternatives and modifications are possible within the scope of the appended claims.

Terms such as booster may include a small metal tube containing a secondary high explosive that is crimped onto the end of the detonating cord. The explosive element is designed to provide reliable detonation transfer between the perforating gun or other explosive device and is typically used as an auxiliary explosive to ensure detonation.

Detonating cords are cords containing a high explosive material encased in a flexible housing for connecting the detonator to a main high explosive charge, such as a shaped charge. This provides a very rapid initiation sequence that can be used to fire multiple shaped charges simultaneously.

The detonator or initiation means may comprise means comprising primary explosive material for initiating an explosive sequence comprising one or more shaped charges. Two common types may include an electrically conductive detonator and an impact detonator. The detonator may be referred to as an initiator. The conductive detonator has a detonator material that burns when a high voltage is applied to detonate the primary explosive. The percussion detonator contains an abrasive and a primary high explosive charge in a sealed container detonated by a firing pin. The impact force of the striker is sufficient to excite the ballistic sequence, which is then transmitted to the detonating cord.

The initiator may be used to initiate a perforating gun, cutter, setting tool, or other high energy device downhole. For example, cutters are used to cut tubulars using concentrated energy. Setting tools use pyrotechnics to generate gas to work in downhole tools. Any downhole device employing an initiator may be suitable for use with the modular initiator assemblies disclosed herein.

As shown in the exemplary embodiment of fig. 1-8, the perforating gun includes a housing 10, the housing 10 having external threads 13 and a baffle 11 at one end (externally threaded end) and internal threads 40 at the other end (internally threaded end). The thread is tapered and/or self-sealing. This allows the perforating gun housing 10 to provide a pressure seal between the interior and exterior of the housing 10, without relying on an o-ring. This allows for simplified manufacturing and reduced associated costs by reducing the number of mechanical processes required to manufacture the perforating gun housing 10. This also allows for simplified assembly of the perforating gun and reduced associated costs by reducing the number of parts and processes required.

The external and internal threads may also be timed (also known as clocked) such that when the threaded connection between perforating guns is completed, the cuts (scaled) 12 and/or perforating charges of adjacent perforating guns are aligned with each other. The timed alignment of the perforating charges and/or cuts 12 of adjacent perforating guns by the threaded connection allows the entire string of perforating guns to be oriented without the use of alignment members or orienting members and/or locking rings between the perforating guns.

Perforating guns typically, but not always, have a kerf 12 or machined thin wall region aligned with the exit jet of perforating shaped charges. Examples of the present description may or may not have the slit 12.

As shown in fig. 3, each perforating gun includes a charge tube 15, 25 within a gun housing 10, 20, respectively. Between each perforating gun is a pressure spacer 11. In the exemplary embodiment, first gun housing 10 having cutout 12 is coupled to second gun housing 20 having cutout 22. When the tapered threads 13 of the male threaded end of the first gun housing 10 are connected with the threads 43 of the female threaded end of the second gun housing 20, there is a point of contact where the threads initially contact, which is also aligned with the cutouts 12 and 22. The purpose of the pressure barrier/baffle 11 is to protect the interior of each perforating gun from the pressure that may be present inside an adjacent perforating gun. This pressure may be caused by a leakage of wellbore pressure into the interior of the perforating gun, by pressure created by detonation of an explosive within the perforating gun, or by balancing of the wellbore pressure into the perforating gun housing 10 through the apertures formed by the perforating charges. Typically, an o-ring provides a pressure seal between the pressure bulkhead/baffle 11 and the perforating gun carrier or housing 10. The second perforating gun housing 20 has a second partition 21 for connecting to the third perforating gun housing.

In the example of fig. 4, an o-ring groove can be seen in the spacer 11, which can be used to provide a pressure seal between the spacer 11 and the perforating gun housing 10. The upper end fitting 16 on the loading tube is fitted with integral selective perforation switches. Such switches are typically addressable to allow selective firing of individual perforating guns in a perforating gun string. The switch may also include an orientation detector (e.g., a gyroscope and/or accelerometer) that provides data regarding the orientation of the switch and, accordingly, the perforating charge. In the example of fig. 4, the pressure bulkhead/bottom contact within bulkhead 11 provides an electrical connection at the bottom of the perforating gun that is connected to the interior of perforating gun housing 20 (e.g., to the switch). An upper end fitting 16, which mates with spacer 11, provides a pressure seal between the interior of gun housing 10 and the wellbore or adjacent gun. The upper end fitting 16 also includes a top contact that provides an electrical connection at the top of the perforating gun that connects to the interior of the perforating gun, for example to a switch. The charge tube 15 includes a cutout 19 for mounting the shaped charge.

Alternatively, the perforating gun may not include a switch. In the example, where no switch is present in each perforating gun, the electrical connection still conveys the electrical signal from one perforating gun to the other.

Figure 5 shows a detailed view of the connection between two perforating guns. The first perforating gun housing 10 with the conical threads 13 is connected to the second perforating gun housing 20 with the internal threads 43. In this example, the spacer 11 includes a larger diameter sealing portion having shoulders on each side that then engage corresponding shoulders 31 on the adjacent perforating gun housing 20. This results in a sealed portion of the spacer 11 between two adjacent perforating gun housings 10, 20. This engagement provides a metal-to-metal high pressure seal 33 between adjacent perforating guns. This arrangement eliminates the need for an external o-ring. Fig. 5 also shows the seal provided by tapered self-sealing threads in adjacent gun carriers. End fitting 17 is shown supporting charge tube 15. The bottom contact 18 provides electrical communication through the spacer 11. The springs 32 provide additional contact support within the spacer 11. End fitting 26 supports a charge tube 25 having shaped charge cutout 29.

These example features are further illustrated in fig. 6-8. The first perforating gun housing 10 is connected to the second perforating gun housing 20. The slit 12 and the slit 22 are aligned. The alignment is provided by the timing thread. The gun carrier may include positive stops 45 aligned with the cuts 12 and 22 to provide specific engagement for timing the threads on adjacent gun housings to ensure that the cuts 12 and 22 are aligned when the two gun housings 10, 20 reach their junction 34. The limit stop 45 may be a face that is angled with respect to the long axis of the gun carriage 50. In this case, when the threaded joint between the adjacent perforating gun housings 10, 20 is assembled, the applied torque can be converted into an axial force, thereby improving the engagement between the threads of the adjacent perforating gun carriers and further improving the sealing and pressure resistance. In some examples, the angle of the limit stop 45 may be 45 degrees.

In some examples, not all of these features may be present. In various examples, the key features may be present in any combination. For example, a tool string (a tool string) may have a perforating gun with timing threads that are not necessarily self-sealing, but rather use a conventional sealing mechanism (e.g., an o-ring). In another example, the tool string may have a perforating gun without timing threads, but the threads of the perforating gun are self-sealing and a conventional sealing mechanism (e.g., an o-ring) may not be used. In another example, the tool string may include a perforating gun with a bump stop or beveled bump stop without the need for timing threads and self-sealing threads, or without the need for timing threads or self-sealing threads.

These modifications may also be combined with an orientation sensor or orientation sensing switch to confirm the orientation of each perforating gun prior to and/or upon firing.

While the invention has been described in terms of the embodiments set forth in detail, it should be understood that this is by way of example only and that the invention is not necessarily limited thereto. For example, terms such as upper and top, or lower and bottom, may be replaced uphole and downhole, respectively. The top and bottom may be left and right sides, respectively. The wellhead and downhole may be shown as left and right sides, respectively, or as top and bottom, respectively, in the figures. Typically, the downhole tool initially enters the borehole in a vertical direction, but since some of the borehole ends in a horizontal direction, the direction of the tool may change. In this case, the downhole, lower or bottom is typically the component of the tool string that enters the borehole before what is called the wellhead, upper or top. The first housing and the second housing may be a top housing and a bottom housing, respectively. In a gun string as described herein, the first gun may be an uphole gun or a downhole gun, as with the second gun, and the uphole or downhole references may be interchanged as they are merely used to describe the positional relationship of the various components. Terms such as wellbore, borehole, well, wellbore, oil well, and other alternatives may be used as synonyms. Terms such as tool string, tool, perforating gun string, or downhole tool, and other alternative terms may be used as synonyms. Alternative embodiments and operating techniques will become apparent to those skilled in the art based on this disclosure. Accordingly, modifications may be made without departing from the spirit of the claimed invention.

Claims (20)

1. A perforating gun system, comprising: a first perforating gun having a housing and a first set of cutouts, the first perforating gun housing having a first end and a second end having a first alignment mechanism, The alignment mechanism is aligned with the first set of incisions; a second perforating gun having a housing and a second set of cutouts, the second perforating gun housing having a first end having a second alignment mechanism, The second alignment mechanism is connected to the first alignment mechanism at the second end of the first perforating gun, and the second set of cuts is aligned with the second alignment mechanism, wherein the first perforation The gun is connected to the second perforating gun such that the first set of cuts are aligned with the second set of cuts. 2. The perforating gun system of claim 1, wherein the first alignment mechanism is a timing external thread. 3. The perforating gun system of claim 2, wherein the second alignment mechanism is a timing external thread. 4. The perforating gun system of claim 1, further comprising at least one o-ring seal between the second end of the first perforating gun and the first end of the second perforating gun . 5. The perforating gun system of claim 1, further comprising a stop at the point of full engagement between the second end of the first perforating gun and the first end of the second perforating gun. Stoppers. 6. The perforating gun system of claim 5, wherein the stop is a bevel that resists rotation beyond a predetermined point of thread engagement. 7. The perforating gun system of claim 6, wherein the stop is a 45 degree slope. 8. The perforating gun system of claim 3, wherein the timing external threads and timing internal threads are self-sealing. 9. The perforating gun system of claim 3, further comprising a stop at the point of full engagement between the second end of the first perforating gun and the first end of the second perforating gun. Stoppers. 10. The perforating gun system of claim 9, wherein the stop is a bevel that resists rotation beyond a predetermined point of thread engagement. 11. The perforating gun system of claim 10, wherein the stop is a 45 degree slope. 12. A perforating gun system, comprising: a first perforating gun, the first perforating gun having a housing and a first set of cutouts, the first perforating gun housing having a first end and a second end having a timing external thread, the third a set of cuts aligned with said timing external threads; a second perforating gun having a housing and a second set of cutouts, the second perforating gun housing having a first end having internally timed threads for passage Timing threads are connected to the second end of the first perforating gun, the second set of cuts are aligned with the internal timing threads, wherein the external timing threads fully engage the internal timing threads such that the The first set of cuts is aligned with the second set of cuts. 13. The perforating gun system of claim 12, further comprising at least one o-ring seal between the second end of the first perforating gun and the first end of the second perforating gun . 14. The perforating gun system of claim 12, further comprising a stop at the point of full engagement between the second end of the first perforating gun and the first end of the second perforating gun. Stoppers. 15. The perforating gun system of claim 14, wherein the stop is a bevel that resists rotation beyond a predetermined point of thread engagement. 16. The perforating gun system of claim 15, wherein the stop is a 45 degree slope. 17. The perforating gun system of claim 12, wherein the timing external threads and timing internal threads are self-sealing. 18. A method of assembling a perforating gun string, comprising: Screw the first timing thread of the first perforating gun into the second timing thread of the second perforating gun; Aligning the first set of notches on the first perforating gun with the second set of notches on the second perforating gun; Fully engaging the first timing thread of the first perforating gun with the second timing thread of the second perforating gun, wherein the full engagement of the first perforating gun with the second perforating gun causes The first set of cuts are aligned with the second set of cuts. 19. The method of assembling a perforating gun string according to claim 18, further comprising: The stop is engaged when the first timing threads of the first perforating gun engage the second timing threads of the second perforating gun. 20. A method of assembling a perforating gun string according to claim 18, wherein complete engagement of the first perforating gun and the second perforating gun results in an interior of the perforating gun string and the A pressure seal is provided between the exteriors of the gun strings.